VLAN protocol

ABSTRACT

A generally full-wire throughput, switching Ethernet controller used within an Ethernet network of other switching Ethernet controllers connected together by a bus. The controller comprises a plurality of ports including at least one bus port associated with ports connected to other switching Ethernet controllers. A hash table stores MAC addresses and VLAN ids of ports within said Ethernet network. A hash table address control hashes the MAC address and VLAN id of a packet to initial hash table location values, changes the hash table location values by a fixed jump amount if the address and VLAN id values stored in said initial hash table location do not match the received address and VLAN id, and provides at least an output port number of the port associated with the received address and VLAN id. A storage buffer includes a multiplicity of contiguous buffers in which to temporarily store said packet.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Divisional application of U.S. patent application Ser. No. 10/293,098, filed Nov. 12, 2002, which is a continuation of application Ser. No. 09/348,864 filed on Jul. 7, 1999, the contents of which are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to virtual local area networks (VLAN) protocols in general.

BACKGROUND OF THE INVENTION

A network switch creates a local area network (LAN) among a plurality of end nodes, such as workstations, and other network switches connected thereto. Each end node is connected to one port of the network. The ports also serve to connect network switches together.

Each end node sends packets of data to the network switch which the switch then routes either to another of the end nodes connected thereto or to a network switch to which the destination end node is connected. In the latter case, the receiving network switch routes the packet to the destination end node.

Each network switch has to temporarily store the packets of data, which it receives from the units (end node or network switch) connected to it while the switch determines how, when and through which port to retransmit the packets. Each packet can be transmitted to only one destination address (a “unicast” packet) or to more than one unit (a “multicast” or “broadcast” packet). For multicast and broadcast packets, the switch typically stores the packet only once and transmits multiple copies of the packet to some (multicast) or all (broadcast) of its ports. Once the packet has been transmitted to all of its destinations, it can be removed from the memory of the switch or written over.

Each end node has an address, known as a media access control (MAC) address, which is unique to that end node. Each switch maintains an address-table, where each entry is composed of a MAC address and at least its device and port location on that end node.

Network switches can be arranged into architecture groupings, known as virtual LANs (VLANs), which enable a selected number of computers to operate together in a subdivision. Each end node in the VLAN communicates only with the other member end nodes. Thus, if end nodes of the same switch are part of different VLANs, they will not be able to communicate with each other.

Reference is now made to FIGS. 1, 2 and 3 which, respectively, illustrates a basic switching network, the table elements of one switch S1 and details of an associated VLAN table 10. The LAN comprises a multiplicity of computers C1-C15 connected together via a multiplicity of switches, S1, S2 and S3, each having a plurality of ports P1-P7. Each switch comprises ports P1 to P5 each of which connects to one of computers Ci, and ports P6 and P7, which connect to another switch.

Each computer has a MAC address within the network and each switch S includes a global address table 12 which lists each MAC address, its associated switch and port location and at least one of the VLANs to which it belongs. For example, computer C4 is located at (P4, S1); computer C7 is located at (P2, S2); and computer C14 is located at (P5, S3).

The VLAN addresses are additionally compiled in a global VLAN table 14, such as that shown in FIG. 2, which lists each VLAN id and its associated port members, where the port members are defined by at least the port and switch location. The VLAN table is generally 4K entries (VLAN ids) long and 256 bit (port members) wide, and each switch in the network has a copy of it. Consequently, each switch is able to draw from its associated VLAN table the address information of every end node in the network.

The exemplary global VLAN table of FIG. 3 applies to the network illustrated in FIG. 1 and lists the applicable VLAN ids 16 and their associated port members 18. As an example, VLAN id 1 comprises the end nodes located at (P1, S1), (P4, S1), (P2, S2), (P3, S2), (P4, S3) and (P5, S3): and VLAN id 12-2 comprises the end nodes located at (P1, S1), (P3, S1), and (P5, S1); and so on.

Generally, when a switch S receives a packet on a port P, the packet includes the source and destination MAC addresses as well as the VLAN id of the source and destination computers. The packet is submitted to two processes: learning and forwarding.

In the learning process, the switch S searches in the global address table 12 for the source MAC address, which is the MAC address of the port, which sent the packet, together with the VLAN id. If the source MAC address was previously learned for the VLAN id, then switch S will find the MAC address and VLAN id in global address table 12 and the switch S does not need to update table 12. However, if the source MAC address was not learned before, for that VLAN id, then the switch S verifies that the source port is a member of that VLAN, and if so, switch S will learn or update the MAC address with that VLAN id.

In the forwarding process, the switch S searches for the destination MAC address with the VLAN id in global address table 12. If the (destination MAC and VLAN id) address is not found, then the switch S sends the packet to all the members of the VLAN listed in the packet. To do so, switch S retrieves the membership of the VLAN id from global VLAN table 14 and forwards the packet to all the members of that VLAN.

If, on the other hand, the destination address and VLAN id are found, then the address table 12 contains the switch and port location for that station, and the packet is forwarded to that port (which may be on the same switch S or on another switch).

SUMMARY OF THE PRESENT INVENTION

A generally full-wire throughput, switching Ethernet controller used within an Ethernet network of other switching Ethernet controllers connected together by a bus. The controller comprises a plurality of ports including at least one bus port associated with ports connected to other switching Ethernet controllers. A hash table stores MAC addresses and VLAN ids of ports within said Ethernet network. A hash table address control hashes the MAC address and VLAN id of a packet to initial hash table location values, changes the hash table location values by a fixed jump amount if the address and VLAN id values stored in said initial hash table location do not match the received address and VLAN id, and provides at least an output port number of the port associated with the received address and VLAN id. A storage buffer includes a multiplicity of contiguous buffers in which to temporarily store said packet.

Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be understood and appreciated more fully from the following detailed description taken in conjunction with the drawings in which:

FIG. 1 is a schematic illustration of a local area network (LAN) of switches;

FIG. 2 is a schematic illustration of a prior art switch;

FIG. 3 is a schematic illustration of a prior art virtual LAN (VLAN) table associated with the network of FIG. 1;

FIG. 4 is a schematic illustration of a switch, constructed and operative in accordance with a preferred embodiment of the present invention;

FIGS. 5A, 5B and 5C are schematic illustrations of local VLAN tables for three switches, constructed and operative in accordance with a preferred embodiment of the present invention;

FIG. 6 is a schematic illustration of a hash table address recognition unit, constructed and operative in accordance with a preferred embodiment of the present invention;

FIG. 7 is a block diagram illustration of the logic elements of the address recognition unit of FIG. 6;

FIG. 8 is a schematic diagram of a function for creating a NEW MAC address which is a combination of the VLAN id and MAC address;

FIG. 9 is a schematic diagram of a hash function, useful in the address recognition unit of FIG. 6; and

FIG. 10 is a schematic diagram of a hash function, useful in the address recognition unit of FIG. 6.

DETAILED DESCRIPTION OF THE PRESENT INVENTION

Reference is now made to FIG. 4 which illustrates a switch, constructed and operative in accordance with a preferred embodiment of the present invention, having local VLAN tables 20 and to FIGS. 5A, 5B and 5C which illustrate, in general terms, local VLAN tables 20A, 20B and 20C, respectively. FIGS. 5A, 5B and 5C are the local VLAN tables stored, in accordance with a preferred embodiment of the present invention, in switches S1, S2, and S3, respectively, of the network of FIG. 1.

As indicated in FIG. 4, each switch S has a global address table 12, as in the prior art. However, in accordance with a preferred embodiment of the present invention, each switch S replaces the global VLAN table of the prior art with a local VLAN table 20.

As shown in FIGS. 5A, 5B and 5C, each local VLAN table 20 lists the VLAN identifier (id) 22 of each VLAN, the local ports 24 belonging to that VLAN id and the other switches 26 of the network which also have ports belonging to that VLAN id. Other information about the local ports can also be stored per VLAN id.

The following discussion will use the VLAN memberships of FIG. 3 as an example. Thus, VLAN table 20A (FIG. 5A) of switch S1 lists that local ports P1 and P4 are members of VLAN 1, and that switches S2 and S3 also have ports, which are members of VLAN 1. Additionally, VLAN table 20A lists that local ports P1, P3 and P5 are members of VLAN 2. Since this is the complete list of members of VLAN 2, no other switches are listed in the other switches column 26. Furthermore, switch S1 does not have any local port members of VLAN 3; however, VLAN table 20A lists that switches S2 and S3 have members of that VLAN. Lastly, VLAN table 20A lists port P4 as a local member of VLAN 4 with remote members in switch S2.

VLAN tables 20B and 20C for switches S2 and S3, respectively, are similarly arranged. For example, VLAN tables 20B and 20C list no local ports for VLAN 2 but both indicate that switch S1 has members of that VLAN.

It will be appreciated that storing only the local port membership and the switch membership for remote ports reduces the size of the VLAN tables compared to the prior art. For example, the local port membership can be accommodated with 8 bits and the switch membership can be accommodated with 32 bits, instead of holding 8×32 bits or 256 bits per VLAN id as in the prior art.

It is noted that the operation of the present invention with the local VLAN tables 20 is similar to that described in the prior art, except for the operation when the destination address is not found. In this case, the switch S uses its local VLAN table 20 to forward the packet to all of its local ports P that are members of that VLAN, and to all the switches S that have member ports P. The receiving switches S will look up the port members for that VLAN and forward the packet to them.

Reference is now made to FIGS. 6 and 7, which illustrate a hash table control unit 52, which controls access to the address table 12 implemented as a hash table. FIG. 6 illustrates the hash table control unit 52 and its operation and FIG. 7 details the elements of unit 52. The term “location” will be utilized to refer to addresses within the hash table 212.

Hash table control unit 52 comprises a hash table 212 and a hash table location generator 214. Hash table 212 is shown with only 18 locations; it will be appreciated that this is for the purposes of clarity only. Typically, hash table 212 will have 48K locations therein and, in accordance with the present invention, each location stores one MAC address and its associated VLAN id and port.

Location generator 214 receives the VLAN Id and the MAC address, whether of the source end node or of the destination end node, and transforms that combined address, via a hash function, to a table location. The hash function can be any suitable hash function; two suitable functions are provided herein below with respect to FIGS. 8 and 9.

In accordance with the present invention, if the generated table location stores a combined address which is not the same as the VLAN id and MAC address provided as input, the location generator 214 generates a second location which is X locations further down in the hash table 212. The hash table does not store any pointers to the next location. In accordance with the present invention, X is a prime number such that, if it is necessary to move through the entire hash table 212, each location will be visited only once during the review.

For example, and as shown in FIG. 6, X is 5 and the first table location is the location labeled 1. If the VLAN id and the MAC address of location 2 does not match that of the input VLAN id and MAC address, the location generator 214 “jumps” to location 6 (as indicated by arrow 220), and then to location 11 (arrow 222), and then to location 16 of the hash table 212 (arrow 224). Since there are only 18 locations in the hash table 212 of FIG. 6, location generator 214 then jumps to location 3 (arrow 226), which is (16+5) mod 18. If location 4 is also full, location generator 214 will generate locations until all of the locations of table 212 have been visited.

It will be appreciated that the hash table control unit 52 does not need to have pointers in table 212 pointing to the “next” location in the table. As a result, unit 52 knows, a priori, which locations in the table are next and can, accordingly, generate a group of locations upon receiving the VLAN id and the MAC address. If desired, the data in the group of locations can be read at once and readily compared to the input VLAN id and the MAC address.

FIG. 7 illustrates the elements of the location generator 214 and its operation in conjunction with the table 212. Location generator 214 comprises a hash function generator 230, DRAM interface 56 (since the hash table 212 is typically implemented in DRAM 20), a latch 234 and a comparator 236.

The hash function generator 230 converts a 48-bit combination of the VLAN id and the MAC address MA to the table location TL₀ of 15 bits. The DRAM interface 56 generates the group of next table locations TL₀, TL₁ and TL₂, where TL₁=TL₀+X and TL₂=TL₀+2×, etc. It will be appreciated that FIG. 7 illustrates only three table locations but many more or many less can be generated at once, as desired.

DRAM interface 56 accesses the table 212 to read the addresses, A₀, A₁ and A₂, and their associated data d₀, d₁ and d₂, stored in table locations TL₀, TL₁ and TL₂, respectively. The data d_(i) includes the necessary information about the address, such as the switch identification number and any other desired information. The read operation can be performed at once or successively.

The output of each table location is latched by latch 234. Comparator 236 then compares the address information A_(i) with that of MAC address MA. If the two addresses match (i.e. a “hit”), then comparator 236 indicates to latch 234 to output the associated data d_(i) stored therein. Otherwise, comparator 236 indicates to DRAM interface 56 to read the address A_(i) and associated data d_(i) stored in the next table location.

If many table locations are to be read at once, the location generator 214 can include a multiplicity of latches 234, one for each location to be read at once.

If one of the table locations is empty, as indicated by a valid bit of the data d_(i), all locations after it will also be empty. Thus, the input VLAN id and MAC address have no corresponding stored address and therefore, the input VLAN id and MAC address is typically input into the empty table location. The valid bit in the associated data d_(i) is then set to ‘not empty’.

FIGS. 8 and 9, to which reference is now made, respectively illustrate a method for combining the VLAN id and MAC address into a “NEW MAC” address and an exemplary hash function, which can be performed by hash function generator 230.

As shown in FIG. 8, the VLAN id is divided into four sections of three bits. To create the NEW MAC address, generator 230 includes three exclusive OR units (XORs) 240, 244 and 246 and a concatenator 248. The result of the XORing, the output of XOR 246, is concatenated (in concatenator 248) with portions of the MAC address. The order of concatenation is: MAC[47:42]: output of XOR 246: MAC[38:0].

As shown in FIG. 9, generator 230 considers only the 33 highest significant bits (HSBs) of the NEW MAC address. The 33 HSBs are divided into five bytes, labeled E, F, G, H and J. Byte E consists of bits 40:45, byte F consists of bits 15:23, byte G consists of bits 24:32, byte H consists of bits 33:39 and byte J consists of bits 46:47. Bytes F and G both are of 9 bits, byte H is of 7 bits and byte J is of 2 bits.

Hash function generator 230 comprises two XOR units 340A and 340B, two concatenators 342 and 343 and a swap unit 344. The concatenator 342 concatenates the bytes J and H. The XOR unit 340A performs an exclusive OR between byte G and the output of concatenator 342. The XOR unit 340B performs an exclusive OR between the output of XOR unit 340A and byte F, thereby producing a variable of 9 bits. Concatenator 343 concatenates the output of XOR unit 240B with byte E, thereby producing variable T<14:07> of 8 bits. Swap unit 344 swaps the bits of variable T<14:07> to produce the output table location TL<14:07>. Thus, the value of TL<14> receives the value of T<07>, the value of TL<13> receives that of T<08>, etc.

FIG. 10, to which reference is now made, illustrates another exemplary hash function, on the NEW MAC address, which can be performed by hash function generator 230. As in the previous embodiment, generator 230 considers only the 33 highest significant bits (HSBs) of the NEW MAC address. The 33 HSBs are divided into four bytes, labeled K, L, M and N. Byte K Consists of bits 15:23, byte L Consists of bits 24:32, byte M Consists of bits 33:41 and byte N Consists of bits 42:47. Thus, byte N is 6 bits and the remaining bytes are 9 bits.

For this embodiment, hash function generator 230 comprises two XOR units 440A and 440B, a concatenator 442 and a swap unit 444. The XOR unit 240A performs an exclusive OR between bytes L and M. The XOR unit 440B performs an exclusive OR between the output of XOR unit 440A and byte K. Concatenator 442 concatenates the output of XOR unit 440B with byte N, thereby producing variable T of 15 bits. As before, swap unit 444 swaps the bits of variable T to produce the output table location TL.

It will be appreciated that any hash function can be utilized. However, the desired hash functions are those, which provide a uniform distribution of table locations for the expected MAC addresses. It is noted that the above hash function is easily implemented in hardware since XOR units and concatenators are simple to implement.

It will be appreciated by persons skilled in the art that the present invention is not limited by what has been particularly shown and described herein above. Rather the scope of the invention is defined by the claims that follow: 

1. A generally full-wire throughput, switching Ethernet controller for use within an Ethernet network of other switching Ethernet controllers connected together by a bus, the controller comprising: a plurality of ports including at least one bus port associated with ports connected to other switching Ethernet controllers; a hash table for storing MAC addresses and VLAN ids of ports within said Ethernet network; and a hash table address control for hashing the MAC address and VLAN id of a packet to initial hash table location values and for changing the hash table location values by a fixed jump amount if the address and VLAN id values stored in said initial hash table location do not match the received address and VLAN id.
 2. A switch controller comprising: a plurality of ports including at least one bus port associated with ports connected to other switching controllers; a hash table for storing MAC addresses and VLAN ids of ports within a network; and a hash table address controller for hashing the MAC address and VLAN id of a packet to initial hash table location values, for changing the hash table location values by a fixed offset if the address and VLAN id values stored in said initial hash table location do not match the received address and VLAN id, and for providing at least an output port number of the port associated with the received address and VLAN id.
 3. The controller of claim 2 further comprising a storage buffer including a multiplicity of contiguous buffers in which to temporarily store said packet.
 4. A method for operating a switch controller comprising: providing a plurality of ports including at least one bus port associated with ports connected to other switching controllers; storing MAC addresses and VLAN ids of ports within a network in a hash table; hashing the MAC address and VLAN id of a packet to initial hash table location values; changing the hash table location values by a fixed jump amount if the address and VLAN id values stored in said initial hash table location do not match the received address and VLAN id; providing at least an output port number of the port associated with the received address and VLAN id; and temporarily storing said packet.
 5. A method for operating a switch controller comprising: providing a plurality of ports including at least one bus port associated with ports connected to other switching controllers; storing MAC addresses and VLAN ids of ports within a network in a hash table; hashing the MAC address and VLAN id of a packet to initial hash table location values; changing the hash table location values by a fixed offset if the address and VLAN id values stored in said initial hash table location do not match the received address and VLAN id; and providing at least an output port number of the port associated with the received address and VLAN id.
 6. The method of claim 5 further comprising temporarily storing said packet.
 7. The controller of claim 1 wherein the hash table address control provides at least an output port number of the port associated with the received address and VLAN id.
 8. The controller of claim 1 further comprising a storage buffer including a multiplicity of contiguous buffers in which to temporarily store said packet.
 9. A method for operating a switch controller comprising: providing a plurality of ports including at least one bus port associated with ports connected to other switching controllers; storing MAC addresses and VLAN ids of ports within a network in a hash table; hashing the MAC address and VLAN id of a packet to initial hash table location values; and changing the hash table location values by a fixed jump amount if the address and VLAN id values stored in said initial hash table location do not match the received address and VLAN id.
 10. The method of claim 9 further comprising: providing at least an output port number of the port associated with the received address and VLAN id.
 11. The method of claim 9 further comprising: temporarily storing said packet. 